Superconducting cable

The invention claimed is: 1. A superconducting cable comprising a core part, in which the core part includes a former including a plurality of copper wires, a superconducting conductor layer including a plurality of superconducting wires, an insulating layer, and a superconducting shield layer including a plurality of superconducting wires are sequentially arranged, wherein the former and the superconducting wires of the superconducting conductor layer are connected in parallel to each other, wherein a conducting layer formed of a metal having a current-carrying property at room temperature is provided on opposite surfaces of each of the superconducting wires of the superconducting conductor layer to reinforce mechanical rigidity of each of superconducting wires of the superconducting conductor layer, and wherein the former has a cross-sectional area which is smaller than that of a former of a superconducting cable in which the conducting layer is not added to superconducting wires and which is designed on an assumption that all fault current flows to the former. 2. The superconducting cable of claim 1 , wherein a minimum cross-sectional area of the former of the core part satisfies a minimum short-circuit condition of 50 KA/sec or 25 KA/0.5 sec. 3. The superconducting cable of claim 1 , wherein, in the superconducting cable to which superconducting wires having added thereto no conducting layer and having a width of x mm and a thickness of y mm is applied, if a minimum cross-sectional area of the former satisfying a minimum short-circuit condition which is a minimum current-carrying rate condition required for a predetermined time when an electrical short-circuit accident occurs is A mm2 or more, the conducting layer is formed of a brass material, and a semiconductor wire having added thereto the conducting layer has a width of x mm and a thickness of 3y to 5y, the former has a minimum cross-sectional area of 0.6 A mm2 to 0.9 A mm2. 4. The superconducting cable of claim 1 , wherein the superconducting wires comprise a silver (Ag) layer, and the conducting layer and the silver (Ag) layer of each of the superconducting wires of the superconducting conductor layer are electrically connected to each other by soldering side surfaces of the superconducting wires or coating surfaces of the superconducting wires with a metal. 5. The superconducting cable of claim 1 , wherein tensile strength of the superconducting wires having added thereto the conducting layer is 200 Mpa to 800 Mpa with respect to a 95 percent current attenuation (IC relentation) criterion. 6. The superconducting cable of claim 1 , wherein the conducting layer added to the opposite surfaces of each of the superconducting wires has a thickness of 0.1 mm to 0.2 mm. 7. A superconducting cable comprising: a former; at least one-layer superconducting conductor layer including a plurality of superconducting wires arranged in parallel at an outer side of the former and in a lengthwise direction of the former; and at least one-layer superconducting shield layer including a plurality of superconducting wires arranged in parallel at an outer side of the superconducting conductor layer and in the lengthwise direction of the former, wherein the superconducting wires of the superconducting conductor layer and the superconducting shield layer comprise: a metal substrate layer; a plurality of deposition layers deposited on the metal substrate layer, the deposition layers including a superconducting layer; and a silver (Ag) layer provided at an outer side of the deposition layers and formed of a silver material, wherein a conducting layer formed of a metal having a current-carrying property at room temperature is added to opposite outer surfaces of the metal substrate layer and the silver (Ag) layer of the superconducting wires, the conducting layer used as a return conductor of fault current when the fault current is generated, together with the former, and wherein a minimum cross-sectional area of the former satisfying a minimum short-circuit condition which is a minimum current-carrying rate condition required for a predetermined time during occurrence of an electrical short-circuit accident is smaller when a metal conducting layer having a predetermined thickness is provided at both the outer sides of the metal substrate layer and the silver (Ag) layer of the superconducting wires than when the metal conducting layer is not included in the superconducting wire. 8. The superconducting cable of claim 7 , wherein the metal used to form the conducting layer is a brass material. 9. The superconducting cable of claim 7 , wherein the conducting layer has a thickness of 0.1 mm to 0.2 mm. 10. The superconducting cable of claim 7 , wherein the minimum short-circuit condition is 50 KA/sec or 25 KA/0.5 sec. 11. The superconducting cable of claim 7 , wherein the conducting layer is soldered onto the superconducting wires. 12. The superconducting cable of claim 11 , wherein solders for soldering the conducting layer onto the superconducting wires comprise tin (Sn), lead (Pb), and silver (Ag), and have a melting point of 200° C. or less. 13. The superconducting cable of claim 7 , wherein surfaces of the superconducting wires are plated with copper or side surfaces of the superconducting wires are soldered to use the conducting layer as a return conductor of fault current, together with the metal substrate layer and the silver (Ag) layer of the superconducting wires. 14. A superconducting cable comprising: a plurality of conductor wires compressed into a round shape or a cylindrical pipe shape; a plurality of superconducting wires arranged at outer sides of the conductor wires to form an at least one-layer superconducting conductor layer; insulating paper configured to form an insulating layer by winding outer sides of the superconducting wires forming the superconducting conductor layer a plurality of times; a former; and a plurality of superconducting wires arranged at an outer side of the insulating paper to form an at least one-layer superconducting shield layer, wherein a thin metal layer is added to opposite surfaces of each of the superconducting wires of the superconducting conductor layer and the superconducting shield layer, wherein the former has a cross-sectional area which is smaller than that of a former of a superconducting cable in which the thin metal layer is not added to superconducting wires and the superconducting shield layer and which is designed on an assumption that all fault current flows to the former. 15. The superconducting cable of claim 14 , wherein the thin metal layer is formed of a brass material to a thickness of 0.1 mm to 0.2 mm. 16. The superconducting cable of claim 14 , wherein the thin metal layer is soldered using solders formed of tin (Sn), lead (Pb), and silver (Ag). 17. The superconducting cable of claim 14 , wherein, in order to electrically connect the superconducting wires and the thin metal layer to each other, side surfaces of the superconducting wires are soldered or surfaces of the superconducting wire are coated with copper, and the thin metal layer is used as a return circuit of fault current. 18. The superconducting cable of claim 14 , wherein tensile strength of the superconducting wires having added thereto the thin metal layer is 200 Mpa to 800 Mpa with respect to a 95% current attenuation (IC relentation) criterion.